Abstract
Quality and quantity of food items consumed has a crucial effect on phenotypes. In addition to direct effects mediated by nutrient resources, an individual’s diet can also affect the phenotype indirectly by altering its gut microbiota, a potent modulator of physiological, immunity and cognitive functions. However, most of our knowledge of diet-microbiota interactions is based on mammalian species, whereas little is still known about these effects in other vertebrates. We developed a metabarcoding procedure based on cytochrome c oxidase I high-throughput amplicon sequencing and applied it to describe diet composition in breeding colonies of an insectivorous bird, the barn swallow (Hirundo rustica). To identify putative diet-microbiota associations, we integrated the resulting diet profiles with an existing dataset for faecal microbiota in the same individual. Consistent with previous studies based on macroscopic analysis of diet composition, we found that Diptera, Hemiptera, Coleoptera and Hymenoptera were the dominant dietary components in our population. We revealed pronounced variation in diet consumed during the breeding season, along with significant differences between nearby breeding colonies. In addition, we found no difference in diet composition between adults and juveniles. Finally, our data revealed a correlation between diet and faecal microbiota composition, even after statistical control for environmental factors affecting both diet and microbiota variation. Our study suggests that variation in diet induce slight but significant microbiota changes in a non-mammalian host relying on a narrow spectrum of items consumed.
Highlights
IntroductionQuality and quantity of food items consumed has a crucial effect on phenotypes. In addition to direct effects mediated by nutrient resources, an individual’s diet can affect the phenotype indirectly by altering its gut microbiota, a potent modulator of physiological, immunity and cognitive functions
The preferred diet may vary with age due to differing nutritional demands related to specific ontogenetic s tages[6]
polymerase chain reaction (PCR) amplification failed in 34 samples; we only sequenced 106 individuals (23 adults and 83 juveniles) for the c oxidase subunit I (COI) profile
Summary
Quality and quantity of food items consumed has a crucial effect on phenotypes. In addition to direct effects mediated by nutrient resources, an individual’s diet can affect the phenotype indirectly by altering its gut microbiota, a potent modulator of physiological, immunity and cognitive functions. Our study suggests that variation in diet induce slight but significant microbiota changes in a nonmammalian host relying on a narrow spectrum of items consumed. In addition to the direct consequences of nutrient compounds on fitness-related traits, diet variation may impose indirect effects by modulating populations of microbial symbionts hosted in the digestive tract of a given individual. This gut microbiota represents the largest fraction of microbial symbionts associated with animal hosts in terms of both cell count and encoded g enes[7,8]. Most studies undertaken on birds have found some support for the effect of diet on interspecific variation, Scientific Reports | (2022) 12:3787
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