Abstract
Bacterial gene transfer agents (GTAs) are small virus-like particles that package DNA fragments and inject them into cells. They are encoded by gene clusters resembling defective prophages, with genes for capsid head and tail components. These gene clusters are usually assumed to be maintained by selection for the benefits of GTA-mediated recombination, but this has never been tested. We rigorously examined the potential benefits of GTA-mediated recombination, considering separately transmission of GTA-encoding genes and recombination of all chromosomal genes. In principle GTA genes could be directly maintained if GTA particles spread them to GTA- cells often enough to compensate for the loss of GTA-producing cells. However, careful bookkeeping showed that losses inevitably exceed gains for two reasons. First, cells must lyse to release particles to the environment. Second, GTA genes are not preferentially replicated before DNA is packaged. A simulation model was then used to search for conditions where recombination of chromosomal genes makes GTA+ populations fitter than GTA- populations. Although the model showed that both synergistic epistasis and some modes of regulation could generate fitness benefits large enough to overcome the cost of lysis, these benefits neither allowed GTA+ cells to invade GTA- populations, nor allowed GTA+ populations to resist invasion by GTA- cells. Importantly, the benefits depended on highly improbable assumptions about the efficiencies of GTA production and recombination. Thus, the selective benefits that maintain GTA gene clusters over many millions of years must arise from consequences other than transfer of GTA genes or recombination of chromosomal genes.
Highlights
Some bacteria are known to produce phage-like particles that contain short fragments of chromosomal DNA (Marrs, 1974; Lang et al, 2012, 2017; Québatte et al, 2017; Tamarit et al, 2018)
We initially focused on two models where DNA transfer by gene transfer agents (GTAs) particles directly benefits the GTA genes responsible for particle production, by transferring either the whole GTA cluster or single GTA-gene alleles
GTAs clearly arise by deletion and recombination processes that place prophage structural and DNA-packaging genes under the control of cellular regulators, and these results suggest they are actively maintained by natural selection acting on benefits they confer
Summary
Some bacteria are known to produce phage-like particles that contain short fragments of chromosomal DNA (Marrs, 1974; Lang et al, 2012, 2017; Québatte et al, 2017; Tamarit et al, 2018). Gene transfer agent (GTA) particles are typically encoded by a cluster of head, tail and DNA-packaging genes strongly resembling those of known temperate phages. Genes for the RcGTA capsid (head, tail, and DNA packaging) are together in a 14 kb cluster; head spikes, tail fibers, and a holin and endolysin are encoded separately (Lang et al, 2017). In lab cultures these genes are most active in stationary phase, reflecting the combined actions of at least two phosphorelays and a quorum-sensing system, all of which contribute to regulation of other cellular processes [summarized by Lang et al (2017)]. Burst sizes are not known, but consideration of the R. capsulatus genome size (3,872 kb), the DNA capacity of the particles, and the maximum titer of particles transducing a specific marker [about 2 × 106/ml (Solioz et al, 1975)] suggests that culture supernatants can contain at least 2 × 109 GTA particles/ml
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