Insights into gene expression changes under conditions that facilitate horizontal gene transfer (mating) of a model archaeon

Andrea M Makkay,Nikhil Ram-Mohan,R Thane Papke,Uri Gophna,J Peter Gogarten,Artemis S Louyakis

doi:10.1038/s41598-020-79296-w

Andrea M Makkay, Nikhil Ram-Mohan + Show 4 more

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https://doi.org/10.1038/s41598-020-79296-w

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Horizontal gene transfer is a means by which bacteria, archaea, and eukaryotes are able to trade DNA within and between species. While there are a variety of mechanisms through which this genetic exchange can take place, one means prevalent in the archaeon Haloferax volcanii involves the transient formation of cytoplasmic bridges between cells and is referred to as mating. This process can result in the exchange of very large fragments of DNA between the participating cells. Genes governing the process of mating, including triggers to initiate mating, mechanisms of cell fusion, and DNA exchange, have yet to be characterized. We used a transcriptomic approach to gain a more detailed knowledge of how mating might transpire. By examining the differential expression of genes expressed in cells harvested from mating conditions on a filter over time and comparing them to those expressed in a shaking culture, we were able to identify genes and pathways potentially associated with mating. These analyses provide new insights into both the mechanisms and barriers of mating in Hfx. volcanii.

Highlights

The physiology of mating in Hfx. volcanii involves cellular fusion via the formation of a cytoplasmic bridge followed by bidirectional transfer of DNA and ends with cell cleavage
Genes implicated in mediating cell shape may potentially be involved in formation of the cytoplasmic bridge and many of those genes have a pattern of expression consistent with mating warranting further examination
Expression of the host defense, CRISPR-Cas and RM Systems, are activated under mating conditions, likely limiting recombination and defending against nonself, invading DNA, and suggesting post-fusion barriers against mating are present in Hfx. volcanii

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Introduction

The physiology of mating in Hfx. volcanii involves cellular fusion via the formation of a cytoplasmic bridge followed by bidirectional transfer of DNA and ends with cell cleavage. SNARE/DedA family proteins in Haloarchaea do not have a clear transcriptional pattern to connect them to the mating process, but the mating pattern is not in conflict with that hypothesis.

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