A three-dimensional habitat for C. elegans environmental enrichment

Aurélie Guisnet,Michael Hendricks,Sreeparna Pradhan,Malosree Maitra,Sean P Curran

doi:10.1371/journal.pone.0245139

Aurélie Guisnet, Michael Hendricks + Show 3 more

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https://doi.org/10.1371/journal.pone.0245139

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Journal: PloS one	Publication Date: Jan 11, 2021
Citations: 16	License type: CC BY 4.0

Affiliation: McGill University

Abstract

As we learn more about the importance of gene-environment interactions and the effects of environmental enrichment, it becomes evident that minimalistic laboratory conditions can affect gene expression patterns and behaviors of model organisms. In the laboratory, Caenorhabditis elegans is generally cultured on two-dimensional, homogeneous agar plates abundantly covered with axenic bacteria culture as a food source. However, in the wild, this nematode thrives in rotting fruits and plant stems feeding on bacteria and small eukaryotes. This contrast in habitat complexity suggests that studying C. elegans in enriched laboratory conditions can deepen our understanding of its fundamental traits and behaviors. Here, we developed a protocol to create three-dimensional habitable scaffolds for trans-generational culture of C. elegans in the laboratory. Using decellularization and sterilization of fruit tissue, we created an axenic environment that can be navigated throughout and where the microbial environment can be strictly controlled. C. elegans were maintained over generations on this habitat, and showed a clear behavioral bias for the enriched environment. As an initial assessment of behavioral variations, we found that dauer populations in scaffolds exhibit high-frequency, complex nictation behavior including group towering and jumping behavior.

Highlights

Model organisms are reared in laboratory conditions that are simplified compared to their wild natural environments
These conditions aid in standardization, as we learn more about the importance of gene-environment interactions and the effects of environmental enrichment, it becomes evident that minimalistic laboratory conditions can affect gene expression patterns and behavior in ways that limit rather than enable biological understanding [1, 2]
We showed that animals have a behavioral bias for and express complex nictation behavior as dauers in this habitat, including towering and jumping

Summary

Introduction

Model organisms are reared in laboratory conditions that are simplified compared to their wild natural environments. These conditions aid in standardization, as we learn more about the importance of gene-environment interactions and the effects of environmental enrichment, it becomes evident that minimalistic laboratory conditions can affect gene expression patterns and behavior in ways that limit rather than enable biological understanding [1, 2]. 80% of the baker’s yeast Saccharomyces cerevisiae genes can be deleted under optimal laboratory conditions, but 97% of its genes are essential to survive environmental stressors [3]. Growing evidence suggests that considering a broader range of environmental factors and their effects on traits of interest in model organisms can provide deeper biological insight [5].

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