AbstractIn biotechnological work horses likeStreptococcus thermophilusandBacillus subtilisnatural competence can be induced, which facilitates genetic manipulation of these microbes. However, in strains of the important dairy starterLactococcus lactisnatural competence has not been established to date. However,in silicoanalysis of complete genome sequences of 43L. lactisstrains revealed complete late-competence gene-sets in 2L. lactissubspeciescremorisstrains (KW2 and KW10) and 8L. lactissubspecieslactisstrains, including the model strain IL1403 and the plant-derived strain KF147. The remainder of the strains, including all dairy isolates, displayed genomic decay in one or more of the late competence genes. Nisin-controlled expression of the competence regulatorcomXinL. lactissubsp.lactisKF147 resulted in the induction of expression of the canonical competence regulon, and elicited a state of natural competence in this strain. By contrast,comXexpression inL. lactisNZ9000, predicted to encode an incomplete competence gene-set, failed to induce natural competence. Moreover, mutagenesis of thecomEA-ECoperon in strain KF147, abolished thecomXdriven natural competence, underpinning the involvement of the competence machinery. Finally, introduction of nisin-induciblecomXexpression intonisRK-harboring derivatives of strains IL1403 and KW2 allowed the induction of natural competence also in these strains, expanding this phenotype to otherL. lactisstrains of both subspecies.Significance statementSpecific bacterial species are able to enter a state of natural competence in which DNA is taken up from the environment, allowing the introduction of novel traits. Strains of the speciesLactococcus lactisare very important starter cultures for the fermentation of milk in the cheese production process, where these bacteria contribute to the flavor and texture of the end-product. The activation of natural competence in this industrially relevant organism can accelerate research aiming to understand industrially relevant traits of these bacteria, and can facilitate engineering strategies to harness the natural biodiversity of the species in optimized starter strains.