Abstract
The availability of high-throughput parallel methods for sequencing microbial communities is increasing our knowledge of the microbial world at an unprecedented rate. Though most attention has focused on determining lower-bounds on the -diversity i.e. the total number of different species present in the environment, tight bounds on this quantity may be highly uncertain because a small fraction of the environment could be composed of a vast number of different species. To better assess what remains unknown, we propose instead to predict the fraction of the environment that belongs to unsampled classes. Modeling samples as draws with replacement of colored balls from an urn with an unknown composition, and under the sole assumption that there are still undiscovered species, we show that conditionally unbiased predictors and exact prediction intervals (of constant length in logarithmic scale) are possible for the fraction of the environment that belongs to unsampled classes. Our predictions are based on a Poissonization argument, which we have implemented in what we call the Embedding algorithm. In fixed i.e. non-randomized sample sizes, the algorithm leads to very accurate predictions on a sub-sample of the original sample. We quantify the effect of fixed sample sizes on our prediction intervals and test our methods and others found in the literature against simulated environments, which we devise taking into account datasets from a human-gut and -hand microbiota. Our methodology applies to any dataset that can be conceptualized as a sample with replacement from an urn. In particular, it could be applied, for example, to quantify the proportion of all the unseen solutions to a binding site problem in a random RNA pool, or to reassess the surveillance of a certain terrorist group, predicting the conditional probability that it deploys a new tactic in a next attack.
Highlights
A fundamental problem in microbial ecology is the ‘‘rare biosphere’’ [1] i.e. the vast number of low-abundance species in any sample
The balls represent the different members of the microbial community, and each color is a uniquely defined operational taxonomic unit
Our methodology lends itself better for a sequential analysis and accurate predictions in a logarithmic scale; in particular, in a linear scale–though it relies on randomized sample sizes
Summary
A fundamental problem in microbial ecology is the ‘‘rare biosphere’’ [1] i.e. the vast number of low-abundance species in any sample. Because most species in a given sample are rare, estimating their total number i.e. a-diversity is a difficult task [2,3], and of dubious utility [4,5]. Parametric and non-parametric methods for species estimation show some promise [6,7], microbial communities may not yet have been sufficiently deeply sampled [8] to test the suitability of the models or fit their parameters. Samples from microbial communities may be conceptualized as sampling–with replacement–different colored balls from an urn. The urn represents the environment where samples are taken: soil, gut, skin, etc. The balls represent the different members of the microbial community, and each color is a uniquely defined operational taxonomic unit
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