Universal barrier to lateral spread of specific genes among microorganisms

Abstract

A genetic circuit to suppress the lateral spread of cloned genes from recombinant to indigenous microorganisms in the environment has been developed. It is based on the endonucleolytic activity of the bacterial toxin colicin E3, which has a distinct target at the 3 end of the 16S ribosomal RNA; this sequence is conserved in virtually all prokaryotic and many eukaryotic genera. Cleavage at this sequence separates the mRNA binding sites from the remainder of the 16S rRNA, thereby inhibiting protein synthesis. While host bacteria carrying the genes for both colicin production and colicin immunity are perfectly viable, lateral transfer of the E3 gene to non‐immune reciptents results in killing of such recipients. This genetic circuit decreases operational transfer frequencies of cloned genes linked to the E3 gene among a variety of bacterial genera by four to five orders of magnitude, in combination with transposon cloning vectors, the circuit is predicted to reduce the rate of lateral spread of specific genes to ecologically insignificant levels. This system therefore represents a useful tool both to explore the evolutionary and ecological consequences of experimentally reducing lateral gene spread among microorganisms, and to increase the ecological predictability of novel recombinant microorganisms.