Abstract
High-throughput sequencing technology has helped microbial community ecologists explore ecological and evolutionary patterns at unprecedented scales. The benefits of a large sample size still typically outweigh that of greater sequencing depths per sample for accurate estimations of ecological inferences. However, excluding or not sequencing rare taxa may mislead the answers to the questions ‘how and why are communities different?’ This study evaluates the confidence intervals of ecological inferences from high-throughput sequencing data of foliar fungal endophytes as case studies through a range of sampling efforts, sequencing depths, and taxonomic resolutions to understand how technical and analytical practices may affect our interpretations. Increasing sampling size reliably decreased confidence intervals across multiple community comparisons. However, the effects of sequencing depths on confidence intervals depended on how rare taxa influenced the dissimilarity estimates among communities and did not significantly decrease confidence intervals for all community comparisons. A comparison of simulated communities under random drift suggests that sequencing depths are important in estimating dissimilarities between microbial communities under neutral selective processes. Confidence interval analyses reveal important biases as well as biological trends in microbial community studies that otherwise may be ignored when communities are only compared for statistically significant differences.
Highlights
Microbiology has been revolutionized by high-throughput sequencing (HTS), allowing the investigation of ecological and evolutionary patterns at unprecedented broader and deeper scales, especially for the rare or cryptic microbial biosphere [1,2]
Confidence intervals and precision were emphasized over hypothesis-testing and p values to understand the nature of community dissimilarities estimated with large sampling sizes or deep sequencing depths in the era of HTS
While p-values are robust to testing the probability of differences from null predictions, confidence intervals inform the strength of this effect, which can be compared between different treatments
Summary
Microbiology has been revolutionized by high-throughput sequencing (HTS), allowing the investigation of ecological and evolutionary patterns at unprecedented broader and deeper scales, especially for the rare or cryptic microbial biosphere [1,2]. Until a few years ago, sampling efforts significantly limited ecological and evolutionary inferences for the hyperdiverse foliar fungal endophytes (FFE) because of the time and labor necessary for culturing, isolating, and genotyping individual fungi from plant tissues. High-throughput amplicon sequencing (e.g., ITS rDNA sequencing), has transformed the field by allowing more.
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