Abstract
Eukaryotes have occasionally acquired genetic material through horizontal gene transfer (HGT). However, little is known about the evolutionary and functional significance of such acquisitions. Lysozymes are ubiquitous enzymes that degrade bacterial cell walls. Here, we provide evidence that two subclasses of bivalves (Heterodonta and Palaeoheterodonta) acquired a lysozyme gene via HGT, building on earlier findings. Phylogenetic analyses place the bivalve lysozyme genes within the clade of bacteriophage lysozyme genes, indicating that the bivalves acquired the phage-type lysozyme genes from bacteriophages, either directly or through intermediate hosts. These bivalve lysozyme genes underwent dramatic structural changes after their co-option, including intron gain and fusion with other genes. Moreover, evidence suggests that recurrent gene duplication occurred in the bivalve lysozyme genes. Finally, we show the co-opted lysozymes exhibit a capacity for antibacterial action, potentially augmenting the immune function of related bivalves. This represents an intriguing evolutionary strategy in the eukaryote–microbe arms race, in which the genetic materials of bacteriophages are co-opted by eukaryotes, and then used by eukaryotes to combat bacteria, using a shared weapon against a common enemy.
Highlights
It has been well established that horizontal gene transfer (HGT), the movement of genetic materials between distinct evolutionary lineages, plays an essential role in the evolution of prokaryotic genomes [1,2,3]
The 11 bivalve species used in this study belong to two subclasses of Bivalvia: Heterodonta and Palaeoheterodonta
Phylogenetic analysis shows that both Wenbei and Qicaibei belong to the subclass of Heterodonta
Summary
It has been well established that horizontal gene transfer (HGT), the movement of genetic materials between distinct evolutionary lineages, plays an essential role in the evolution of prokaryotic genomes [1,2,3]. During the establishment of the mitochondrion and the plastid, large amounts of genetic material from the endosymbionts were transferred to the eukaryotic nuclear genomes. The ongoing, subsequent HGT events in eukaryotes have long been underappreciated [3]. More and more cases of HGT have been reported in eukaryotes [3]. Several distinct lysozyme classes have been described, including hen egg-white lysozyme (HEWL; glycoside hydrolase 22 [GH22]), goose egg-white lysozyme (GEWL or GH23), bacteriophage T4 lysozyme (T4 L or GH24) and GH25
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