Flow Cytometric Single-Cell Identification of Populations in Synthetic Bacterial Communities.

Peter Rubbens,Ruben Props,Nico Boon,Willem Waegeman,Peter E Larsen

doi:10.1371/journal.pone.0169754

Peter Rubbens, Ruben Props + Show 3 more

Open Access

https://doi.org/10.1371/journal.pone.0169754

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Journal: PloS one	Publication Date: Jan 25, 2017
Citations: 32	License type: CC BY 4.0

Affiliation: Ghent University

Abstract

Bacterial cells can be characterized in terms of their cell properties using flow cytometry. Flow cytometry is able to deliver multiparametric measurements of up to 50,000 cells per second. However, there has not yet been a thorough survey concerning the identification of the population to which bacterial single cells belong based on flow cytometry data. This paper not only aims to assess the quality of flow cytometry data when measuring bacterial populations, but also suggests an alternative approach for analyzing synthetic microbial communities. We created so-called in silico communities, which allow us to explore the possibilities of bacterial flow cytometry data using supervised machine learning techniques. We can identify single cells with an accuracy >90% for more than half of the communities consisting out of two bacterial populations. In order to assess to what extent an in silico community is representative for its synthetic counterpart, we created so-called abundance gradients, a combination of synthetic (i.e., in vitro) communities containing two bacterial populations in varying abundances. By showing that we are able to retrieve an abundance gradient using a combination of in silico communities and supervised machine learning techniques, we argue that in silico communities form a viable representation for synthetic bacterial communities, opening up new opportunities for the analysis of synthetic communities and bacterial flow cytometry data in general.

Highlights

Microbial communities are primary contributors in most biogeochemical processes on Earth [1]
The main goal of this paper is to explore in a systematic way the possibilities of using Flow cytometry (FCM) data to identify bacterial single cells, in order to be able to characterize the composition of synthetic bacterial communities
We conclude that for a majority of in silico communities we are able to perform single-cell predictions up to high performances, especially when using Random Forests; in this case more than half of our communities report results higher than 0.90 for both area under the receiving operating characteristic (ROC) curve (AUC) and the accuracy

Summary

Introduction

Microbial communities are primary contributors in most biogeochemical processes on Earth [1]. A large portion of microbial research has been dedicated to the study of the structure and functionality within microbial communities of various complexities. These aspects have been largely inferred from research with axenic cultures. The availability of next-generation sequencing technologies has shifted the focus towards the study of microbial taxa directly in their respective environment (’omics). Both approaches suffer from either a lack of complexity (axenic cultures) or a lack of controllability (’omics) [2].

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