In Agrobacterium-mediated transformation (AMT) of plants, a single-strand (ss) T-DNA covalently linked with a VirD2 protein moves through a bacterial type IV secretion channel called VirB/D4. This transport system originates from conjugal plasmid transfer systems of bacteria. The relaxase VirD2 and its equivalent protein Mob play essential roles in T-DNA transfer and mobilizable plasmid transfer, respectively. In this study, we attempted to transfer a model T-DNA plasmid, which contained no left border but had a right border sequence as an origin of transfer, and a mobilizable plasmid through the VirB/D4 apparatus to Escherichia coli, Agrobacterium and yeast to compare VirD2-driven transfer with Mob-driven one. AMT was successfully achieved by both types of transfer to the three recipient organisms. VirD2-driven AMT of the two bacteria was less efficient than Mob-driven AMT. In contrast, AMT of yeast guided by VirD2 was more efficient than that by Mob. Plasmid DNAs recovered from the VirD2-driven AMT colonies showed the original plasmid structure. These data indicate that VirD2 retains most of its important functions in recipient bacterial cells, but has largely adapted to eukaryotes rather than bacteria. The high AMT efficiency of yeast suggests that VirD2 can also efficiently bring ssDNA to recipient bacterial cells but is inferior to Mob in some process leading to the formation of double-stranded circular DNA in bacteria. This study also revealed that the recipient recA gene was significantly involved in VirD2-dependent AMT, but only partially involved in Mob-dependent AMT. The apparent difference in the recA gene requirement between the two types of AMT suggests that VirD2 is worse at re-circularization to complete complementary DNA synthesis than Mob in bacteria.
Horizontal DNA transfer is one of the major driving forces in bacterial evolution. Genes from other bacteria are beneficial from ecological and evolutionary viewpoints, that is, foreign nucleotide sequences could provide new functions and enable the cell to survive in new environments (Ochman et al. 2000). However, in many cases, foreign DNAs contain genes that encode something hazardous, such as toxins, and the addition of foreign nucleotide sequences disturbs currently working genetic systems (Kobayashi 2004; Hall et al. 2017; Baltrus 2013). Restriction endonucleases are firewalls against the entry of foreign DNAs, such as phage DNAs (Luria & Human 1952; Bertani & Weigle 1953; Tock & Dryden 2005). In addition, nucleases other than restriction enzymes are likely to play roles in the degradation of foreign DNAs (Roer et al. 2015).
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